Wheel bearing assembly

ABSTRACT

A wheel bearing assembly for use in an automotive vehicle includes a wheel hub. A rotary constant velocity joint drives the wheel hub and the outer member of the constant velocity joint is an integral part of the wheel hub. A bearing is mounted on a tubular part of the wheel hub and includes an outer bearing ring and a two-part inner bearing ring. A retaining ring secures the two-part inner bearing ring on the tubular part of the wheel hub. The retaining ring is secured in a groove in the tubular part and in the secured position it is plastically deformed and pretensions the inner bearing ring.

SUMMARY OF THE INVENTION

The present invention is directed to a bearing assembly for a wheel hub driven by a rotary constant velocity joint and secured to an associated wheel carrier on a motor vehicle. The bearing assembly includes an outer bearing ring and a two-part inner bearing ring. The outer bearing ring is arranged to be connected to the wheel carrier. The wheel hub and the outer joint member of the rotary constant velocity joint are formed as a unit. The two-part inner bearing ring is axially supported against a shoulder formed on the wheel hub.

As shown in West German Patentschrift No. 25 05 081 bearings of this type having divided inner bearing rings are known. To assure satisfactory functioning of such two-part, non-adjustable tapered bead seat bearings, the bearings must be tensioned in the axial direction by high pretensioning forces. Such pretensioning forces are applied by forming a thread in the axle shaft and applying axially directed forces by securing a nut on the thread.

In other bearing assemblies, such as in the West German Patentschrift No. 14 80 912, it is known to position the wheel bearing approximately outwardly about the joint center to afford small vehicle turning circles. As a consequence, the thread diameter is increased and due to the required minimum pitch values, the tightening moments for the retaining rings are required such that they cannot be safely achieved using standard wrenches.

Therefore, it is the primary object of the present invention to provide a bearing assembly for an automotive wheel unit using a divided inner bearing ring arranged so that the inner bearing ring can be axially pretensioned to a desired extent.

In accordance with the present invention the end of the inner bearing ring of the bearing assembly closer to the rotary constant velocity joint is fixed in the axial direction by a retaining ring. The retaining ring is held in a groove formed on the outer surface of the portion of the wheel hub forming the outer joint member.

In accordance with the present invention, by purposefully deforming the retaining ring securing the two-part inner bearing ring in position, a sufficient axial pretensioning of the inner bearing ring can be achieved. Such axial pretensioning is afforded by a sheet metal ring supported against one end face of the two-part inner bearing ring with the opposite end face held against a shoulder formed in a groove in the outer joint member constructed integrally with the wheel hub. The required axial pretensioning is attained by deliberately plastically deforming the retaining ring as it is inserted into a groove for holding the two-part inner bearing ring. To accommodate the various tolerances between the bearing rings and the remaining components, a definite flow behavior of the material of the retaining ring is needed to that at least a minimum axial pressure affording the desired pretensioning forces is achieved. Moreover, a predetermined maximum axial pressure must not be exceeded to ensure proper functioning of the bearing assembly. The minimum axial pressure is an amount greater than eight tons.

To assure sufficient support for the retaining ring, another feature of the present invention is that the groove into which the retaining ring is inserted has surfaces extending at an angle to the axial direction of the wheel hub and its associated rotary constant velocity joint.

When the retaining ring is placed into the groove and against one end of the two-part inner bearing ring, it is plastically deformed providing the desired pretensioning effect.

In accordance with the present invention, the retaining ring is deformed until the yield point is reached for assuring a uniform pretension around the entire circumference of the bearing ring. To facilitate this procedure, the retaining ring is made of a material having a definite flow behavior.

Another feature of the present invention is that the surfaces forming the groove have a frusto-conical shape. In accordance with the present invention, the greatest resistance moments of the retaining ring are obtained when the ring is supported on the frusto-conically shaped surfaces of the groove formed in the tubular part of the wheel hub.

In one embodiment of the present invention, initially the retaining ring has a curved cross-section, however, after being inserted into the groove in the tubular part of the wheel hub it assumes a straight or frusto-conical cross-section.

The advantage of this arrangement is that the retaining ring exceeds its yield point and thereby applies a uniform and sufficiently high pretension around the entire circumference of the two-part inner bearing ring.

The various features of novelty which characterize the invention are pointed out with particularity in the claims annexed to and forming a part of this disclosure. For a better understanding of the invention, its operating advantages and specific objects attained by its use, reference should be had to the accompanying drawings and descriptive matter in which there are illustrated and described preferred embodiments of the invention.

BRIEF DESCRIPTION OF THE DRAWING

In the drawing:

FIG. 1 is an axially extending view, partly in section, of a wheel bearing including a rotary constant velocity joint;

FIG. 2 is an enlarged detail view of one embodiment of the groove shown in FIG. 1; and

FIGS. 3-6 are cross sectional views of a number of different embodiments of a retaining ring insertable into the groove shown in FIG. 2.

DETAIL DESCRIPTION OF THE INVENTION

In FIG. 1 a motor vehicle wheel bearing assembly is illustrated including a wheel hub 1 including an axially extending tubular extension 2 with an outer joint member 3 of a rotary constant velocity joint being formed as a part of the wheel hub. The wheel hub has a first end and a second end spaced apart in the axial direction with the outer joint member 3 located at the second end of the wheel hub. As in rotary constant velocity joints, the outer joint member 3 defines an inner hollow space having axially extending grooves 4. An inner joint member 5 is located within the hollow space and it also has axially extending grooves 6. Balls 7 held in windows of a cage 8 extend into a pair of opposite grooves 4 and 6 for transmitting torque between the inner and outer joint members 3, 5. A shaft 9 has a splined end secured within a correspondingly shaped opening in the inner joint part. While a splined connection is shown the shaft 9 and inner joint member 5 can be secured together by other attachment means. The constant velocity joint is enclosed and sealed on one side by a bellows 10 secured to the shaft 9 and to the outer surface of the second end of the wheel hub 1 and, on the other side, by a sheet metal cap 11 held within the tubular part of the wheel hub by a rubber ring 12. The sheet metal cap 11 is pressed into the tubular extension 2 of the wheel hub.

A bearing is positioned on the axially extending tubular extension 2 between the first and second ends and includes a two-part inner bearing ring consisting of the ring parts 13, 14. The outer face of the ring parts 13, 14 is grooved for receiving the balls 15. The bearing includes an outer bearing ring 16 spaced outwardly from and encircling the ring parts 13, 14. Outer bearing ring 16 is also provided with grooves in the inner surface disposed opposite the grooves in the outer surface of the ring parts 13, 14 so that a double-row angular contact ball bearing, a so-called Radiax bearing, is provided.

The two-part inner bearing ring made up of the ring parts 13, 14 of the Radiax bearing are secured on the outside surface of the tubular extension 2 between a shoulder 17 formed in the tubular extension of the wheel hub 1 and a retaining ring 18. The ring part 13 bears against the shoulder 17. The other ring part 14 is located between the ring part 13 and the second end of the tubular extension 2 and is forced against the ring part 13 by the retaining ring 18. Retaining ring 18 is seated within a groove 19 extending around the outer surface of the tubular extension 2 at the end of the ring part 14 closer to the outer joint member 3. As shown in FIG. 2, the groove 19 is formed in the outer surface 20 of the outer joint member 3.

When the retaining ring 18 is pressed into the groove 19 it is plastically deformed with its material flowing in such a way that a sufficiently high axial pressure is produced. This axial pressure provides a pretensioning force which remains in a range between a minimum lower limit and a maximum upper limit.

In FIG. 2 a detail view is provided of the groove 19 formed in the outer surface of the outer joint member 3. The groove 19 has a pair of surfaces extending angularly relative to the axis of the tubular extension 2. Each of the surfaces 21, 22 forms a frusto-conical surface around the axis of the wheel hub. When the retaining ring 18 is forced into the groove 19 it seats against both of the surfaces 21, 22 and presses the ring part 14 against the ring part 13 which in turn is forced against the shoulder 17.

FIGS. 3, 4, 5 and 6 each show a different embodiment of the retaining ring 18. Each of the retaining rings illustrated has a different cross-section providing a different pretensioning force after the retaining ring is deformed when it is inserted into the groove 19. 

We claim:
 1. Wheel bearing assembly such as used on a motor vehicle and arranged to be attached to a wheel carrier of the motor vehicle comprising a wheel hub including an axially extending tubular part having an axially extending inner surface and an axially extending outer surface, a rotary constant velocity joint arranged to drive said wheel hub, said tubular part having a first end and a second end spaced apart in the axial direction, a bearing located on the outer surface of said tubular part and including an outer bearing ring arranged to be connected to the wheel carrier of the motor vehicle, an inner bearing ring located within said outer bearing ring and comprising a first ring part and a second ring part arranged in contacting relation one following the other in the axial direction of said tubular part, said constant velocity joint including an outer joint member and an inner joint member, said outer joint member is formed integrally with said tubular part and is located adjacent the second end of said tubular part, the outer surface of said tubular part forming an annular shoulder facing toward the second end of said tubular part, said first ring part bearing against said shoulder on said tubular part, an annular groove formed in the outer surface of said tubular part between said shoulder and the second end of said tubular part, a retaining ring fitted within said groove in the outer surface of said tubular part and bearing against said second ring part for pressing said second ring part against said first ring part and pressing said first ring part against said shoulder, said ring comprising at least two surfaces extending angularly of one another and said surfaces extending angularly of the axis of tubular part, and said retaining ring is formed of a plastically deformable material so that after said retaining ring is plastically deformed as it is pressed into said groove, said ring produces a pretensioning effect on said ring parts.
 2. Wheel bearing assembly, as set forth in claim 1, wherein said surfaces of said groove each form a frusto-conical surface encircling the axis of said tubular part.
 3. Wheel bearing assembly, as set forth in claim 1, wherein said retaining ring has a curved cross-section prior to the insertion of said ring into said groove and after said ring is pressed into said groove its curved surface is transformed into a straight line surface.
 4. Wheel bearing assembly, as set forth in claim 1, wherein said surfaces of said groove extend angularly to radii of said tubular part of said wheel hub.
 5. Wheel bearing assembly, as set forth in claim 1, wherein said groove has a triangular shape in section in the axial direction of said tubular part. 